/******************************************************************** * COPYRIGHT: * Copyright (c) 1997-2013, International Business Machines Corporation and * others. All Rights Reserved. ********************************************************************/ #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include "dcfmapts.h" #include "unicode/currpinf.h" #include "unicode/dcfmtsym.h" #include "unicode/decimfmt.h" #include "unicode/fmtable.h" #include "unicode/localpointer.h" #include "unicode/parseerr.h" #include "unicode/stringpiece.h" #include "putilimp.h" #include "plurrule_impl.h" #define LENGTHOF(array) ((int32_t)(sizeof(array)/sizeof((array)[0]))) // This is an API test, not a unit test. It doesn't test very many cases, and doesn't // try to test the full functionality. It just calls each function in the class and // verifies that it works on a basic level. void IntlTestDecimalFormatAPI::runIndexedTest( int32_t index, UBool exec, const char* &name, char* /*par*/ ) { if (exec) logln((UnicodeString)"TestSuite DecimalFormatAPI"); switch (index) { case 0: name = "DecimalFormat API test"; if (exec) { logln((UnicodeString)"DecimalFormat API test---"); logln((UnicodeString)""); UErrorCode status = U_ZERO_ERROR; Locale saveLocale; Locale::setDefault(Locale::getEnglish(), status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Could not set default locale, test may not give correct results"); } testAPI(/*par*/); Locale::setDefault(saveLocale, status); } break; case 1: name = "Rounding test"; if(exec) { logln((UnicodeString)"DecimalFormat Rounding test---"); testRounding(/*par*/); } break; case 2: name = "Test6354"; if(exec) { logln((UnicodeString)"DecimalFormat Rounding Increment test---"); testRoundingInc(/*par*/); } break; case 3: name = "TestCurrencyPluralInfo"; if(exec) { logln((UnicodeString)"CurrencyPluralInfo API test---"); TestCurrencyPluralInfo(); } break; case 4: name = "TestScale"; if(exec) { logln((UnicodeString)"Scale test---"); TestScale(); } break; case 5: name = "TestFixedDecimal"; if(exec) { logln((UnicodeString)"TestFixedDecimal ---"); TestFixedDecimal(); } break; default: name = ""; break; } } /** * This test checks various generic API methods in DecimalFormat to achieve 100% * API coverage. */ void IntlTestDecimalFormatAPI::testAPI(/*char *par*/) { UErrorCode status = U_ZERO_ERROR; // ======= Test constructors logln((UnicodeString)"Testing DecimalFormat constructors"); DecimalFormat def(status); if(U_FAILURE(status)) { errcheckln(status, "ERROR: Could not create DecimalFormat (default) - %s", u_errorName(status)); return; } status = U_ZERO_ERROR; const UnicodeString pattern("#,##0.# FF"); DecimalFormat pat(pattern, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Could not create DecimalFormat (pattern)"); return; } status = U_ZERO_ERROR; DecimalFormatSymbols *symbols = new DecimalFormatSymbols(Locale::getFrench(), status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Could not create DecimalFormatSymbols (French)"); return; } status = U_ZERO_ERROR; DecimalFormat cust1(pattern, symbols, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Could not create DecimalFormat (pattern, symbols*)"); } status = U_ZERO_ERROR; DecimalFormat cust2(pattern, *symbols, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Could not create DecimalFormat (pattern, symbols)"); } DecimalFormat copy(pat); // ======= Test clone(), assignment, and equality logln((UnicodeString)"Testing clone(), assignment and equality operators"); if( ! (copy == pat) || copy != pat) { errln((UnicodeString)"ERROR: Copy constructor or == failed"); } copy = cust1; if(copy != cust1) { errln((UnicodeString)"ERROR: Assignment (or !=) failed"); } Format *clone = def.clone(); if( ! (*clone == def) ) { errln((UnicodeString)"ERROR: Clone() failed"); } delete clone; // ======= Test various format() methods logln((UnicodeString)"Testing various format() methods"); double d = -10456.0037; int32_t l = 100000000; Formattable fD(d); Formattable fL(l); UnicodeString res1, res2, res3, res4; FieldPosition pos1(0), pos2(0), pos3(0), pos4(0); res1 = def.format(d, res1, pos1); logln( (UnicodeString) "" + (int32_t) d + " formatted to " + res1); res2 = pat.format(l, res2, pos2); logln((UnicodeString) "" + (int32_t) l + " formatted to " + res2); status = U_ZERO_ERROR; res3 = cust1.format(fD, res3, pos3, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: format(Formattable [double]) failed"); } logln((UnicodeString) "" + (int32_t) fD.getDouble() + " formatted to " + res3); status = U_ZERO_ERROR; res4 = cust2.format(fL, res4, pos4, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: format(Formattable [long]) failed"); } logln((UnicodeString) "" + fL.getLong() + " formatted to " + res4); // ======= Test parse() logln((UnicodeString)"Testing parse()"); UnicodeString text("-10,456.0037"); Formattable result1, result2; ParsePosition pos(0); UnicodeString patt("#,##0.#"); status = U_ZERO_ERROR; pat.applyPattern(patt, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: applyPattern() failed"); } pat.parse(text, result1, pos); if(result1.getType() != Formattable::kDouble && result1.getDouble() != d) { errln((UnicodeString)"ERROR: Roundtrip failed (via parse()) for " + text); } logln(text + " parsed into " + (int32_t) result1.getDouble()); status = U_ZERO_ERROR; pat.parse(text, result2, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: parse() failed"); } if(result2.getType() != Formattable::kDouble && result2.getDouble() != d) { errln((UnicodeString)"ERROR: Roundtrip failed (via parse()) for " + text); } logln(text + " parsed into " + (int32_t) result2.getDouble()); // ======= Test getters and setters logln((UnicodeString)"Testing getters and setters"); const DecimalFormatSymbols *syms = pat.getDecimalFormatSymbols(); DecimalFormatSymbols *newSyms = new DecimalFormatSymbols(*syms); def.setDecimalFormatSymbols(*newSyms); def.adoptDecimalFormatSymbols(newSyms); // don't use newSyms after this if( *(pat.getDecimalFormatSymbols()) != *(def.getDecimalFormatSymbols())) { errln((UnicodeString)"ERROR: adopt or set DecimalFormatSymbols() failed"); } UnicodeString posPrefix; pat.setPositivePrefix("+"); posPrefix = pat.getPositivePrefix(posPrefix); logln((UnicodeString)"Positive prefix (should be +): " + posPrefix); if(posPrefix != "+") { errln((UnicodeString)"ERROR: setPositivePrefix() failed"); } UnicodeString negPrefix; pat.setNegativePrefix("-"); negPrefix = pat.getNegativePrefix(negPrefix); logln((UnicodeString)"Negative prefix (should be -): " + negPrefix); if(negPrefix != "-") { errln((UnicodeString)"ERROR: setNegativePrefix() failed"); } UnicodeString posSuffix; pat.setPositiveSuffix("_"); posSuffix = pat.getPositiveSuffix(posSuffix); logln((UnicodeString)"Positive suffix (should be _): " + posSuffix); if(posSuffix != "_") { errln((UnicodeString)"ERROR: setPositiveSuffix() failed"); } UnicodeString negSuffix; pat.setNegativeSuffix("~"); negSuffix = pat.getNegativeSuffix(negSuffix); logln((UnicodeString)"Negative suffix (should be ~): " + negSuffix); if(negSuffix != "~") { errln((UnicodeString)"ERROR: setNegativeSuffix() failed"); } int32_t multiplier = 0; pat.setMultiplier(8); multiplier = pat.getMultiplier(); logln((UnicodeString)"Multiplier (should be 8): " + multiplier); if(multiplier != 8) { errln((UnicodeString)"ERROR: setMultiplier() failed"); } int32_t groupingSize = 0; pat.setGroupingSize(2); groupingSize = pat.getGroupingSize(); logln((UnicodeString)"Grouping size (should be 2): " + (int32_t) groupingSize); if(groupingSize != 2) { errln((UnicodeString)"ERROR: setGroupingSize() failed"); } pat.setDecimalSeparatorAlwaysShown(TRUE); UBool tf = pat.isDecimalSeparatorAlwaysShown(); logln((UnicodeString)"DecimalSeparatorIsAlwaysShown (should be TRUE) is " + (UnicodeString) (tf ? "TRUE" : "FALSE")); if(tf != TRUE) { errln((UnicodeString)"ERROR: setDecimalSeparatorAlwaysShown() failed"); } // Added by Ken Liu testing set/isExponentSignAlwaysShown pat.setExponentSignAlwaysShown(TRUE); UBool esas = pat.isExponentSignAlwaysShown(); logln((UnicodeString)"ExponentSignAlwaysShown (should be TRUE) is " + (UnicodeString) (esas ? "TRUE" : "FALSE")); if(esas != TRUE) { errln((UnicodeString)"ERROR: ExponentSignAlwaysShown() failed"); } // Added by Ken Liu testing set/isScientificNotation pat.setScientificNotation(TRUE); UBool sn = pat.isScientificNotation(); logln((UnicodeString)"isScientificNotation (should be TRUE) is " + (UnicodeString) (sn ? "TRUE" : "FALSE")); if(sn != TRUE) { errln((UnicodeString)"ERROR: setScientificNotation() failed"); } // Added by Ken Liu testing set/getMinimumExponentDigits int8_t MinimumExponentDigits = 0; pat.setMinimumExponentDigits(2); MinimumExponentDigits = pat.getMinimumExponentDigits(); logln((UnicodeString)"MinimumExponentDigits (should be 2) is " + (int8_t) MinimumExponentDigits); if(MinimumExponentDigits != 2) { errln((UnicodeString)"ERROR: setMinimumExponentDigits() failed"); } // Added by Ken Liu testing set/getRoundingIncrement double RoundingIncrement = 0.0; pat.setRoundingIncrement(2.0); RoundingIncrement = pat.getRoundingIncrement(); logln((UnicodeString)"RoundingIncrement (should be 2.0) is " + (double) RoundingIncrement); if(RoundingIncrement != 2.0) { errln((UnicodeString)"ERROR: setRoundingIncrement() failed"); } //end of Ken's Adding UnicodeString funkyPat; funkyPat = pat.toPattern(funkyPat); logln((UnicodeString)"Pattern is " + funkyPat); UnicodeString locPat; locPat = pat.toLocalizedPattern(locPat); logln((UnicodeString)"Localized pattern is " + locPat); // ======= Test applyPattern() logln((UnicodeString)"Testing applyPattern()"); UnicodeString p1("#,##0.0#;(#,##0.0#)"); logln((UnicodeString)"Applying pattern " + p1); status = U_ZERO_ERROR; pat.applyPattern(p1, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: applyPattern() failed with " + (int32_t) status); } UnicodeString s2; s2 = pat.toPattern(s2); logln((UnicodeString)"Extracted pattern is " + s2); if(s2 != p1) { errln((UnicodeString)"ERROR: toPattern() result did not match pattern applied"); } if(pat.getSecondaryGroupingSize() != 0) { errln("FAIL: Secondary Grouping Size should be 0, not %d\n", pat.getSecondaryGroupingSize()); } if(pat.getGroupingSize() != 3) { errln("FAIL: Primary Grouping Size should be 3, not %d\n", pat.getGroupingSize()); } UnicodeString p2("#,##,##0.0# FF;(#,##,##0.0# FF)"); logln((UnicodeString)"Applying pattern " + p2); status = U_ZERO_ERROR; pat.applyLocalizedPattern(p2, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: applyPattern() failed with " + (int32_t) status); } UnicodeString s3; s3 = pat.toLocalizedPattern(s3); logln((UnicodeString)"Extracted pattern is " + s3); if(s3 != p2) { errln((UnicodeString)"ERROR: toLocalizedPattern() result did not match pattern applied"); } status = U_ZERO_ERROR; UParseError pe; pat.applyLocalizedPattern(p2, pe, status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: applyPattern((with ParseError)) failed with " + (int32_t) status); } UnicodeString s4; s4 = pat.toLocalizedPattern(s3); logln((UnicodeString)"Extracted pattern is " + s4); if(s4 != p2) { errln((UnicodeString)"ERROR: toLocalizedPattern(with ParseErr) result did not match pattern applied"); } if(pat.getSecondaryGroupingSize() != 2) { errln("FAIL: Secondary Grouping Size should be 2, not %d\n", pat.getSecondaryGroupingSize()); } if(pat.getGroupingSize() != 3) { errln("FAIL: Primary Grouping Size should be 3, not %d\n", pat.getGroupingSize()); } // ======= Test getStaticClassID() logln((UnicodeString)"Testing getStaticClassID()"); status = U_ZERO_ERROR; NumberFormat *test = new DecimalFormat(status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: Couldn't create a DecimalFormat"); } if(test->getDynamicClassID() != DecimalFormat::getStaticClassID()) { errln((UnicodeString)"ERROR: getDynamicClassID() didn't return the expected value"); } delete test; } void IntlTestDecimalFormatAPI::TestCurrencyPluralInfo(){ UErrorCode status = U_ZERO_ERROR; CurrencyPluralInfo *cpi = new CurrencyPluralInfo(status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: CurrencyPluralInfo(UErrorCode) could not be created"); } CurrencyPluralInfo cpi1 = *cpi; if(cpi->getDynamicClassID() != CurrencyPluralInfo::getStaticClassID()){ errln((UnicodeString)"ERROR: CurrencyPluralInfo::getDynamicClassID() didn't return the expected value"); } cpi->setCurrencyPluralPattern("","",status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: CurrencyPluralInfo::setCurrencyPluralPattern"); } cpi->setLocale(Locale::getCanada(), status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: CurrencyPluralInfo::setLocale"); } cpi->setPluralRules("",status); if(U_FAILURE(status)) { errln((UnicodeString)"ERROR: CurrencyPluralInfo::setPluralRules"); } DecimalFormat *df = new DecimalFormat(status); if(U_FAILURE(status)) { errcheckln(status, "ERROR: Could not create DecimalFormat - %s", u_errorName(status)); } df->adoptCurrencyPluralInfo(cpi); df->getCurrencyPluralInfo(); df->setCurrencyPluralInfo(cpi1); delete df; } void IntlTestDecimalFormatAPI::testRounding(/*char *par*/) { UErrorCode status = U_ZERO_ERROR; double Roundingnumber = 2.55; double Roundingnumber1 = -2.55; //+2.55 results -2.55 results double result[]={ 3.0, -2.0, // kRoundCeiling 0, 2.0, -3.0, // kRoundFloor 1, 2.0, -2.0, // kRoundDown 2, 3.0, -3.0, // kRoundUp 3, 3.0, -3.0, // kRoundHalfEven 4, 3.0, -3.0, // kRoundHalfDown 5, 3.0, -3.0 // kRoundHalfUp 6 }; DecimalFormat pat(status); if(U_FAILURE(status)) { errcheckln(status, "ERROR: Could not create DecimalFormat (default) - %s", u_errorName(status)); return; } uint16_t mode; uint16_t i=0; UnicodeString message; UnicodeString resultStr; for(mode=0;mode < 7;mode++){ pat.setRoundingMode((DecimalFormat::ERoundingMode)mode); if(pat.getRoundingMode() != (DecimalFormat::ERoundingMode)mode){ errln((UnicodeString)"SetRoundingMode or GetRoundingMode failed for mode=" + mode); } //for +2.55 with RoundingIncrement=1.0 pat.setRoundingIncrement(1.0); pat.format(Roundingnumber, resultStr); message= (UnicodeString)"Round() failed: round(" + (double)Roundingnumber + UnicodeString(",") + mode + UnicodeString(",FALSE) with RoundingIncrement=1.0==>"); verify(message, resultStr, result[i++]); message.remove(); resultStr.remove(); //for -2.55 with RoundingIncrement=1.0 pat.format(Roundingnumber1, resultStr); message= (UnicodeString)"Round() failed: round(" + (double)Roundingnumber1 + UnicodeString(",") + mode + UnicodeString(",FALSE) with RoundingIncrement=1.0==>"); verify(message, resultStr, result[i++]); message.remove(); resultStr.remove(); } } void IntlTestDecimalFormatAPI::verify(const UnicodeString& message, const UnicodeString& got, double expected){ logln((UnicodeString)message + got + (UnicodeString)" Expected : " + expected); UnicodeString expectedStr(""); expectedStr=expectedStr + expected; if(got != expectedStr ) { errln((UnicodeString)"ERROR: " + message + got + (UnicodeString)" Expected : " + expectedStr); } } void IntlTestDecimalFormatAPI::verifyString(const UnicodeString& message, const UnicodeString& got, UnicodeString& expected){ logln((UnicodeString)message + got + (UnicodeString)" Expected : " + expected); if(got != expected ) { errln((UnicodeString)"ERROR: " + message + got + (UnicodeString)" Expected : " + expected); } } void IntlTestDecimalFormatAPI::testRoundingInc(/*char *par*/) { UErrorCode status = U_ZERO_ERROR; DecimalFormat pat(UnicodeString("#,##0.00"),status); if(U_FAILURE(status)) { errcheckln(status, "ERROR: Could not create DecimalFormat (default) - %s", u_errorName(status)); return; } // get default rounding increment double roundingInc = pat.getRoundingIncrement(); if (roundingInc != 0.0) { errln((UnicodeString)"ERROR: Rounding increment not zero"); return; } // With rounding now being handled by decNumber, we no longer // set a rounding increment to enable non-default mode rounding, // checking of which was the original point of this test. // set rounding mode with zero increment. Rounding // increment should not be set by this operation pat.setRoundingMode((DecimalFormat::ERoundingMode)0); roundingInc = pat.getRoundingIncrement(); if (roundingInc != 0.0) { errln((UnicodeString)"ERROR: Rounding increment not zero after setRoundingMode"); return; } } void IntlTestDecimalFormatAPI::TestScale() { typedef struct TestData { double inputValue; int inputScale; const char *expectedOutput; } TestData; static TestData testData[] = { { 100.0, 3, "100,000" }, { 10034.0, -2, "100.34" }, { 0.86, -3, "0.0009" }, { -0.000455, 1, "-0%" }, { -0.000555, 1, "-1%" }, { 0.000455, 1, "0%" }, { 0.000555, 1, "1%" }, }; UErrorCode status = U_ZERO_ERROR; DecimalFormat pat(status); if(U_FAILURE(status)) { errcheckln(status, "ERROR: Could not create DecimalFormat (default) - %s", u_errorName(status)); return; } UnicodeString message; UnicodeString resultStr; UnicodeString exp; UnicodeString percentPattern("#,##0%"); pat.setMaximumFractionDigits(4); for(int32_t i=0; i < LENGTHOF(testData); i++) { if ( i > 2 ) { pat.applyPattern(percentPattern,status); } pat.setAttribute(UNUM_SCALE,testData[i].inputScale,status); pat.format(testData[i].inputValue, resultStr); message = UnicodeString("Unexpected output for ") + testData[i].inputValue + UnicodeString(" and scale ") + testData[i].inputScale + UnicodeString(". Got: "); exp = testData[i].expectedOutput; verifyString(message, resultStr, exp); message.remove(); resultStr.remove(); exp.remove(); } } #define ASSERT_EQUAL(expect, actual) { char tmp[200]; sprintf(tmp, "(%g==%g)", (double)(expect), (double)(actual)); \ assertTrue(tmp, ((expect)==(actual)), FALSE, FALSE, __FILE__, __LINE__); } void IntlTestDecimalFormatAPI::TestFixedDecimal() { UErrorCode status = U_ZERO_ERROR; LocalPointer df(new DecimalFormat("###", status)); TEST_ASSERT_STATUS(status); FixedDecimal fd = df->getFixedDecimal(44, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(44, fd.source); ASSERT_EQUAL(0, fd.visibleDecimalDigitCount); df.adoptInstead(new DecimalFormat("###.00##", status)); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(123.456, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(3, fd.visibleDecimalDigitCount); ASSERT_EQUAL(456, fd.decimalDigits); ASSERT_EQUAL(456, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(123, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); df.adoptInstead(new DecimalFormat("###", status)); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(123.456, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(0, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(123, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); df.adoptInstead(new DecimalFormat("###.0", status)); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(123.01, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(1, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(123, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); df.adoptInstead(new DecimalFormat("###.0", status)); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(123.06, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(1, fd.visibleDecimalDigitCount); ASSERT_EQUAL(1, fd.decimalDigits); ASSERT_EQUAL(1, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(123, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); df.adoptInstead(new DecimalFormat("@@@@@", status)); // Significant Digits TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(123, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(123, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); df.adoptInstead(new DecimalFormat("@@@@@", status)); // Significant Digits TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(1.23, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(4, fd.visibleDecimalDigitCount); ASSERT_EQUAL(2300, fd.decimalDigits); ASSERT_EQUAL(23, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(1, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); fd = df->getFixedDecimal(uprv_getInfinity(), status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(TRUE, fd.isNanOrInfinity); fd = df->getFixedDecimal(0.0, status); ASSERT_EQUAL(FALSE, fd.isNanOrInfinity); fd = df->getFixedDecimal(uprv_getNaN(), status); ASSERT_EQUAL(TRUE, fd.isNanOrInfinity); TEST_ASSERT_STATUS(status); // Test Big Decimal input. // 22 digits before and after decimal, will exceed the precision of a double // and force DecimalFormat::getFixedDecimal() to work with a digit list. df.adoptInstead(new DecimalFormat("#####################0.00####################", status)); TEST_ASSERT_STATUS(status); Formattable fable("12.34", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(34, fd.decimalDigits); ASSERT_EQUAL(34, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(12, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); fable.setDecimalNumber("12.345678901234567890123456789", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(22, fd.visibleDecimalDigitCount); ASSERT_EQUAL(345678901234567890LL, fd.decimalDigits); ASSERT_EQUAL(34567890123456789LL, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(12, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); // On field overflow, Integer part is truncated on the left, fraction part on the right. fable.setDecimalNumber("123456789012345678901234567890.123456789012345678901234567890", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(22, fd.visibleDecimalDigitCount); ASSERT_EQUAL(123456789012345678LL, fd.decimalDigits); ASSERT_EQUAL(123456789012345678LL, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(345678901234567890LL, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); // Digits way to the right of the decimal but within the format's precision aren't truncated fable.setDecimalNumber("1.0000000000000000000012", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(22, fd.visibleDecimalDigitCount); ASSERT_EQUAL(12, fd.decimalDigits); ASSERT_EQUAL(12, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(1, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); // Digits beyond the precision of the format are rounded away fable.setDecimalNumber("1.000000000000000000000012", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(1, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); // Negative numbers come through fable.setDecimalNumber("-1.0000000000000000000012", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(22, fd.visibleDecimalDigitCount); ASSERT_EQUAL(12, fd.decimalDigits); ASSERT_EQUAL(12, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(1, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(TRUE, fd.isNegative); // MinFractionDigits from format larger than from number. fable.setDecimalNumber("1000000000000000000000.3", status); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(30, fd.decimalDigits); ASSERT_EQUAL(3, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(100000000000000000LL, fd.intValue); ASSERT_EQUAL(FALSE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); // Test some int64_t values that are out of the range of a double fable.setInt64(4503599627370496LL); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(4503599627370496LL, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); fable.setInt64(4503599627370497LL); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); ASSERT_EQUAL(4503599627370497LL, fd.intValue); ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); fable.setInt64(9223372036854775807LL); TEST_ASSERT_STATUS(status); fd = df->getFixedDecimal(fable, status); TEST_ASSERT_STATUS(status); ASSERT_EQUAL(2, fd.visibleDecimalDigitCount); ASSERT_EQUAL(0, fd.decimalDigits); ASSERT_EQUAL(0, fd.decimalDigitsWithoutTrailingZeros); // note: going through DigitList path to FixedDecimal, which is trimming // int64_t fields to 18 digits. See ticket Ticket #10374 // ASSERT_EQUAL(223372036854775807LL, fd.intValue); if (!(fd.intValue == 223372036854775807LL || fd.intValue == 9223372036854775807LL)) { errln("File %s, Line %d, fd.intValue = %lld", __FILE__, __LINE__, fd.intValue); } ASSERT_EQUAL(TRUE, fd.hasIntegerValue); ASSERT_EQUAL(FALSE, fd.isNegative); } #endif /* #if !UCONFIG_NO_FORMATTING */